Door handle

ABSTRACT

A door handle includes a casing inside which an accommodation space is provided, and a lamp unit disposed in the accommodation space. The lamp unit includes a light emission element, a circuit board on which the light emission element is mounted, a housing that supports the circuit board, and a light guiding lens that guides light emitted from the light emission element in a predetermined direction. The light guiding lens includes an incident surface that receives light emitted from the light emission element, and an emission surface that emits the light entering in the light guiding lens through the incident surface and is positioned below the incident surface. In the door handle, the emission surface is positioned above a lower surface of the casing.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a door handle including a lamp unit in which a light guiding lens guides light in a predetermined direction.

2. Description of Related Art

In some door handles, a circuit board is supported by a housing, a light emission element that functions as a light source is mounted on the circuit board, and light emitted from the light emission element is radiated in a predetermined direction (for example, see Japanese Patent Application Publication 2010-229797 (JP-A-2010-229797), Japanese Patent Application Publication 2009-133133 (JP-A-2009-133133), and Japanese Patent Application Publication 2006-9279 (JP-A-2006-9279)).

JP-A-2010-229797 and JP-A-2009-133133 describe a light unit provided in a door handle that illuminates an area around the user's feet when a door is opened or closed. By illuminating the area around the user's feet, the user can see whether there is a puddle or the like when the door is opened or closed, and thus the user-friendliness increases.

JP-A-2006-9279 also describes a light unit provided in a door handle. In the light unit described in JP-A-2006-9279, an internal space is defined by a housing (case) and a lid, a circuit board is disposed in the internal space, and the light emission element is mounted on the circuit board. A connection code passed through the housing is connected to the circuit board, driving current is supplied to the light emission element via the connection code, and light is emitted from the light emission element in a predetermined direction.

Further, in the door handle described in JP-A-2006-9279, light emitted from the light emission element is radiated outside through a light guide (a diffusion member), and an emission surface of the light guide protrudes outside a casing (panel) of the door handle.

Thus, the light radiated outside tends to become visible directly to people around the door handle. The people who see the light directly may feel dazzling or have difficulty in recognizing objects correctly.

SUMMARY OF THE INVENTION

The invention provides a door handle in which light emitted from a light emission element is made less visible directly to people around the door handle, thereby reducing inconvenience caused by the direct view.

An aspect of the invention relates to a door handle including a casing inside which an accommodation space is provided, and a lamp unit disposed in the accommodation space. The lamp unit includes a light emission element, a circuit board on which the light emission element is mounted, a housing that supports the circuit board, and a light guiding lens that guides light emitted from the light emission element in a predetermined direction. The light guiding lens includes an incident surface that receives light emitted from the light emission element, and an emission surface that emits the light entering in the light guiding lens through the incident surface and is positioned below the incident surface. The emission surface is positioned above a lower surface of the casing.

According to the configuration, the light emission surface of the light guiding lens is positioned inside the casing. As a result, light emitted from the light emission element becomes less visible directly to people around the door handle, and inconvenience caused by the direct view is reduced.

The casing may include a light control surface provided at a lower side of the light guiding lens to be continuous with an outer surface of the light guiding lens, and the light control surface may have a shape flared downward within a predetermined range.

According to the configuration, an illuminated area below the door handle can be restricted, by the light control surface, within the predetermined range in an area that needs to be illuminated.

The door handle may be provided in a vehicle, and in a cross-section of the light guiding lens taken along a right-left direction of the vehicle, a slant angle of an outer edge of the light guiding lens in the right-left direction with respect to an up-down direction of the vehicle may be larger than a slant angle of an inner edge of the light guiding lens in the right-left direction with respect to the up-down direction.

According to the configuration, light is radiated in a direction away from a door panel easily.

The door handle may be provided in a vehicle, and The emission surface may be slanted upward with respect to a plane perpendicular to a light axis of light emitted from the light emission element, in a direction from an outside of the vehicle toward an inside of the vehicle in a right-left direction of the vehicle.

According to the configuration, light is radiated to outside of the vehicle easily.

BRIEF DESCRIPTION OF THE DRAWINGS

Features, advantages, and technical and industrial significance of exemplary embodiments of the invention will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:

FIG. 1 shows an embodiment of the invention together with FIGS. 2 to 8, and is a schematic perspective view showing a door handle joined to a door;

FIG. 2 is a schematic plan view of the door handle;

FIG. 3 is a schematic side view of the door handle;

FIG. 4 is an enlarged cross-sectional view taken along a line IV-IV in FIG. 2;

FIG. 5 is an enlarged cross-sectional view taken along a line V-V in FIG. 3;

FIG. 6 is an enlarged exploded perspective view of a lamp member;

FIG. 7 is an enlarged view showing paths of light emitted from a first light guiding lens; and

FIG. 8 is an enlarged view showing paths of light output from a light guide via a second light guiding lens.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, an embodiment of a door handle according to the invention is explained with reference to the drawings.

The door handle 1 has a shape extending in a front-rear direction of the vehicle, for example, and includes a casing 2 and a lamp unit 12 disposed inside the casing 2, which will be described later (FIGS. 1 to 3). A door handle 1 is used as a handle provided for a door 100 of a vehicle. A joint portion of the door handle 1, which is provided at a front end portion thereof and not shown in the drawings, is joined to a door panel 101 (FIG. 1). A panel concavity 101 a is formed in an outer surface of the door panel 101. The panel concavity 101 a accommodates user's (occupant's) fingers put in an inner side of the door handle 1.

The door handle 1 pivots about the front end portion such that a rear end portion thereof moves in a right-left direction of the vehicle. When the door 100 is opened, the door handle 1 is caused to pivot by the user's operation in a direction in which the rear end portion moves away from the door panel 101. When the user's operation is completed, the door handle 1 is caused to pivot by an urging member, which is not shown in the drawings, in a direction in which the rear end portion moves closer to the door panel 101. Then, the door handle 1 returns to an initial position, which is a position of the door handle 1 before the use's operation.

In the vehicle including the door handle 1, when the user carrying a key for starting an engine of the vehicle approaches the door handle 1 to be within a certain distance from the vehicle, the key is detected by a detection unit (not shown in the drawings) provided in the door handle 1. At this time, the lamp unit 12 (described later) disposed inside the door handle 1 radiates light upon detection of the key. The lamp unit 12 radiates light toward a road surface at least below the door handle 1, and then a road surface around the use's feet is illuminated by the radiated light. Due to the radiated light, the user can see whether there is a puddle or the like when the door 100 is opened or closed during the night. Thus, the user-friendliness increases.

A concaved gripping portion 1 a is provided in the door handle 1 except the front and rear end portions. The concaved gripping portion 1 a is concaved outward, or in a direction away from the door panel 101 (FIGS. 1 and 2). The user (occupant) grips the concaved gripping portion 1 a by putting the fingers in an inner side of the concaved gripping portion 1 a to operate the door handle 1.

The casing 2 includes a first panel 3, a second panel 4, and a inner panel 5 (FIG. 4). The first panel 3 and the second panel 4 are joined to each other in the right-left direction. The first panel 3 is positioned on the outer side and the second panel 4 is positioned on the inner side, i.e., on a side closer to the door panel 101.

In a state where the first panel 3 and the second panel 4 are joined to each other, the inner panel 5 is positioned inside both the panels 3 and 4, at least at a rear end side. An accommodation recess 6 opening generally frontward is provided in the inner panel 5. A positioning pin 7 extending in the generally right-left direction is provided on the inner panel 5 at a position close to a lower edge of the inner panel 5.

An annular-shaped restriction wall portion 8 extending in an up-down direction of the vehicle is provided in a lower end portion of the casing 2. A space inside the restriction wall portion 8 (a space defined by the restriction wall portion 8) communicates with an accommodation space 9 and a space below the door handle 1 (FIGS. 4 and 5). The restriction wall portion 8 is formed by a lower end portion of the second panel 4 and a lower end portion of the inner panel 5 connecting to each other in a circumferential direction of the restriction wall portion 8. The restriction wall portion 8 has a flared internal shape (i.e., a shape in which an internal diameter of the restriction wall portion 8 increases downward). An inner surface of the restriction wall portion 8 is formed as a light control surface 8 a. That is, the light control surface 8 a has a shape flared downward within a predetermined range. In addition, the light control surface 8 a flares more widely in the front-rear direction than in the right-left direction.

Inside the casing 2, the accommodation space 9 extending in the front-rear direction is defined between the first panel 3 and the second panel 4. The accommodation space 9 has a first space 10 and a second space 11. The first space 10 is positioned below the second space 11. The second space 11 opens upward and an opening 11 a at the top is formed as a slit extending in the generally front-rear direction.

A positioning recess 3 a is provided in an inner surface of the first panel 3 except a rear end side portion thereof. The positioning recess 3 a opens toward the second panel 4 and extends in the generally front-rear direction.

A positioning recess 4 a is provided in an inner surface of the second panel 4 except a rear end side portion thereof. The positioning recess 4 a opens toward at least the first panel 3 and extends in the generally front-rear direction. The positioning recess 4 a faces the positioning recess 3 a provided in the first panel 3.

A dividing protrusion 4 b protruding toward the first panel 3 is provided in an intermediate portion of the second panel 4 in the up-down direction. The accommodation space 9 except a portion thereof is divided into the first space 10 and the second space 11 by the dividing protrusion 4 b.

The positioning recess 4 c opening toward the first panel 3 is provided in the second panel 4 at a position close to a lower edge thereof (FIG. 5).

The lamp unit 12 is disposed in the accommodation space 9 defined in the casing 2 (FIGS. 2 to 5). The lamp unit 12 includes a lamp member 13 and a light guide 14.

The lamp member 13 includes a combination member 15 made of a transparent material, a circuit board 16 supported by the combination member 15, a gasket 17 attached to the combination member 15, and a lid member 18 joined to the combination member 15 (FIGS. 4 and 6).

The combination member 15 includes a housing 19, a first light guiding lens 20, and a second light guiding lens 21. The housing 19, the first light guiding lens 20, and the second light guiding lens 21 are integrated as the combination member 15. The combination member 15 is disposed in the first space 10 of the accommodation space 9 with the housing 19 being attached to the casing 2 and at least a portion of the combination member 15 being disposed in the accommodation recess 6 of the inner panel 5.

The housing 19 includes a board mounting portion 22 having a box shape opening upward, a code passage portion 23 protruding downward from a rear end side portion of the board mounting portion 22, a positioning protrusion 24 protruding rearward from the board mounting portion 22 and the code passage portion 23, and joining protrusions 25 provided on right and left side surfaces of the board mounting portion 22.

An inner shape of the board mounting portion 22 is the same as an outer shape of the circuit board 16, and is slightly larger in size than the outer shape of the circuit board 16.

The code passage portion 23 has a tube shape extending in the up-down direction.

The positioning hole 24 a is provided in the positioning protrusion 24. The positioning hole 24 a extends through the positioning protrusion 24 in the right-left direction.

Two joining protrusions 25 are provided on each of the right and left side surfaces of the board mounting portion 22 (FIGS. 5 and 6). The two joining protrusions 25 on the same side surface of the board mounting portion 22 are spaced apart in the front-rear direction.

The first light guiding lens 20 protrudes downward from a front end side portion of the board mounting portion 22 (FIGS. 4 and 6). The first light guiding lens 20 is positioned in front of the code passage portion 23 with a space therebetween.

The first light guiding lens 20 has a columnar shape extending in the up-down direction. The first light guiding lens 20 has a first incident surface 20 a facing upward on an upper end thereof and a first emission surface 20 b on a lower end thereof. The first emission surface 20 b is slanted downward as a distance from the vehicle in the right-left direction increases. In other words, the first emission surface 20 b is slanted upward with respect to a plane perpendicular to a light axis P (an axis extending along the up-down direction) of light emitted from a light emission element 28, which will be described later, in a direction from the outside toward the inside in the right-left direction (FIG. 5). Thus, the first emission surface 20 b is slanted with respect to the light axis P.

The first light guiding lens 20 has a shape in which an outer diameter increases in a direction from the first incident surface 20 a toward the first emission surface 20 b. In a cross-section of the first light guiding lens 20 taken along the right-left direction, a slant angle of an outer edge 20 d thereof in the right-left direction, which corresponds to an outer surface 20 c of the first light guiding lens 20, with respect to the up-down direction is larger than a slant angle of an inner edge 20 e thereof in the right-left direction, which also corresponds to the outer surface 20 c of the first light guiding lens 20, with respect to the up-down direction. Here, the inner edge 20 e is positioned closer to the vehicle than the outer edge 20 d is.

A positioning protrusion 20 f protruding in a lateral direction of the first light guiding lens 20 is provided the first light guiding lens 20 in the at a position close to the lower end.

The second light guiding lens 21 is positioned in front of the first light guiding lens 20 (FIGS. 4 and 6).

The second light guiding lens 21 has a second incident surface 21 a at an upper surface of a lower end portion and a function surface 21 b facing generally forward at an upper end portion. The function surface 21 b functions as a second emission surface.

The second light guiding lens 21 has a first reflection surface 21 c facing downward at the lower end portion, and a second reflection surface 21 d that faces frontward and obliquely downward and is disposed between the first reflection surface 21 c and the function surface 21 b. The second light guiding lens 21 has a third reflection surface 21 e that is continuous with the function surface 21 b and faces rearward and obliquely upward. The third reflection surface 21 e is positioned above the first reflection surface 21 c. In each of the first reflection surface 21 c, the second reflection surface 21 d, and the third reflection surface 21 e, light can be reflected by internal reflection.

As shown in FIGS. 4 and 5, the combination member 15 configured as described above is positioned with respect to the casing 2 by inserting the positioning pin 7 of the inner panel 5 in the positioning hole 24 a provided in the positioning protrusion 24 of the housing 19 and inserting the positioning protrusion 20 f of the first light guiding lens 20 in the positioning recess 4 c provided in the second panel 4. Thus, the combination member 15 is disposed in the first space 10 of the accommodation space 9.

When the combination member 15 is positioned as described above and disposed in the first space 10 of the accommodation space 9, a lower end portion of the first light guiding lens 20 is fitted into an upper end portion of the restriction wall portion 8 of the casing 2. Accordingly, the outer surface 20 c of the first light guiding lens 20 and the light control surface 8 a of the restriction wall portion 8 are provided to be continuous with each other.

In the cross-section of the first light guiding lens 20 taken along the right-left direction, as shown in FIG. 5, the outer edge 20 d corresponding to the outer surface 20 c of the first light guiding lens 20 is in alignment with an edge of the light control surface 8 a, which is continuous with the outer edge 20 d, and the inner edge 20 e corresponding to the outer surface 20 c of the first light guiding lens 20 is in alignment with an edge of the light control surface 8 a, which is continuous with the inner edge 20 e.

As described above, the lower end portion of the first light guiding lens 20 is positioned inside the upper end portion of the restriction wall portion 8 of the casing 2. Thus, the first emission surface 20 b of the first light guiding lens 20 is positioned above the lower surface 2 a of the casing 2 (FIGS. 4 and 5).

The plate-shaped circuit board 16 has a surface (an upper surface 16 a) facing upward and a surface (a lower surface 16 b) facing downward (FIGS. 4 to 6). The circuit board 16 is a double-sided circuit board. A diode 26 having a rectifying function and resistors 27 having a function to restrict current are mounted on a front half portion of the upper surface 16 a of the circuit board 16. A light emission element 28 functioning as a light source that emits light, and a capacitor 29 having a function to store electricity and a discharge function are mounted on a front half portion of the lower surface 16 b of the circuit board 16. The light emission element 28 is positioned in front of the capacitor 29.

A light emitting diode (LED) is used as the light emission element 28, for example. The light emission element 28 is disposed such that a light emission surface 28 a thereof faces downward. The light axis P of light emitted from the light emission element 28 extends along the up-down direction.

Connection codes 30 supply driving current to the light emission element 28 and the like. One end of each connection code 30 is connected to a rear half portion of the circuit board 16 from below by, for example, soldering. The connection codes 30 pass through the first space 10 of the accommodation space 9, and, via a front end portion of the casing 2, pass through the inside of the door 100. The other end of each connection code 30 is connected to a power supply circuit, which is not shown in the drawings.

A bushing 31 is fitted onto a portion of the connection codes 30 near the one end, and protects the connection codes 30 (FIGS. 4 and 6). The bushing 31 is an elastically deformable member made of, for example, a rubber material.

The circuit board 16 is inserted in the board mounting portion 22 from above the housing 19 with the connection codes 30 being connected to the circuit board 16, and then disposed in the board mounting portion 22 (FIGS. 4 and 5).

At this time, the connection codes 30 and the bushing 31 protecting the connection codes 30 are inserted in the code passage portion 23 from above. Thus, the connection codes 30 and the bushing 31 are attached to the housing 19 (FIG. 4). One end portion of the bushing 31 is fitted into the code passage portion 23 with a portion thereof being elastically deformed, and thus displacement of the connection codes 30 and the bushing 31 with respect to the code passage portion 23 is restricted.

As described above, the gasket 17 is attached to the circuit board 16 in a state where the circuit board 16 is disposed in the board mounting portion 22 (FIGS. 4 to 6).

The gasket 17 is attached to the housing 19 with a closing surface portion 32 thereof closing the opening of the board mounting portion 22 (FIGS. 4 and 5), and protects the circuit board 16 disposed in the board mounting portion 22 against water.

As described above, the lid member 18 is joined to the housing 19 in a state where the gasket 17 is attached to the board mounting portion 22. The lid member 18 includes a generally plate-shaped covering surface portion 34 facing the up-down direction, side surface portions 35 respectively extending downward from both sides of the covering surface portion 34 in the right-left direction, a code holding portion 36 provided to be continuous with a lower end portion of one of the side surface portions 35 (FIGS. 4 to 6).

An outer shape of the covering surface portion 34 is the same as an outer shape of the closing surface portion 32 of the gasket 17, and has substantially the same size as the size of the outer shape of the closing surface portion 32.

Joining holes 35 a extending through the side surface portions 35 in the right-left direction are provided in the side surface portions 35. Two joining holes 35 a are provided in each side surface portion 35. The two joining holes 35 a in the same side surface portion 35 are spaced apart in the front-rear direction.

The joining protrusions 25 are engaged with lower edges defining the joining holes 35 a provided in the side surface portions 35, and thus the lid member 18 is joined to the housing 19 (FIGS. 4 and 5).

When the lid member 18 is joined to the housing 19, a portion of each connection code 30 is held by the code holding portion 36.

The light guide 14 as a whole has a shape extending in the generally front-rear direction. A rear end portion of the light guide 14 is disposed above the lamp member 13, and the light guide 14 except the rear end portion is disposed in front of the lamp member 13 (FIGS. 2 and 3).

The light guide 14 is made of the transparent material. The light guide 14 has a wide width portion 37 having the widest width in the up-down direction, an extending portion 38 extending in the generally front-rear direction, and a slant portion 39 extending rearward and obliquely from the wide width portion 37. The wide width portion 37 is positioned close to a rear end of the light guide 14, the extending portion 38 is positioned in front of the wide width portion 37, and the slant portion 39 is positioned behind the wide width portion 37.

A notch 40 opening rearward and generally downward is provided in a lower end portion of the wide width portion 37 (FIG. 4). A rear surface of the wide width portion 37, which defines the notch 40, is formed as a first light entrance surface 40 a, and a lower surface of the wide width portion 37, which defines the notch 40, is formed as a second light entrance surface 40 b. The second light entrance surface 40 b has a stepped shape.

The extending portion 38 has a tapered shape tapering forward (FIG. 3). A lower surface of the extending portion 38 is formed as an internal reflection surface 38 a subjected to surface texturing. Positioning elongated protrusions 38 b protruding in the lateral direction are provided on the extending portion 38 on an intermediate portion in the up-down direction (FIG. 6).

The slant portion 39 has a tapered shape tapering rearward (FIGS. 3 and 5). A rear surface (a surface facing obliquely downward) of the slant portion 39 is formed as an internal reflection surface 39 a subjected to surface texturing. Positioning elongated protrusions 39 b protruding in the lateral direction are provided on the slant portion 39 at a lower end portion (FIGS. 5 and 6).

An upper end portion of the light guide 14 is also subjected to surface texturing. An upper surface of the light guide 14 is formed as a light output surface 14 a.

In the light guide 14, a cover portion 41 is provided at the lower end portion of the wide width portion 37 (FIG. 6). The cover portion 41 is provided at a side of the first light entrance surface 40 a and the second light entrance surface 40 b such that the cover portion 41 faces in the right-left direction.

The light guide 14 is positioned with respect to the casing 2 by inserting the positioning elongated protrusion 38 b and the positioning elongated protrusion 39 b in the positioning recess 3 a provided in the first panel 3 and inserting the positioning elongated protrusion 38 b and the positioning elongated protrusion 39 b in the positioning recess 4 a provided in the second panel 4, respectively (FIGS. 4 and 5). Thus, the light guide 14 is disposed in the first space 10 of the accommodation space 9.

When the light guide 14 is disposed in the first space 10 of the accommodation space 9 as described above, a tip end portion of the second light guiding lens 21 of the lamp member 13 is positioned inside the notch 40 of the light guide 14 (FIG.

4). In the light guide 14, the first light entrance surface 40 a faces the function surface 21 b of the second light guiding lens 21, and the second light entrance surface 40 b faces the third reflection surface 21 e of the second light guiding lens 21.

Further, when the light guide 14 is disposed in the first space 10, the light output surface 14 a is positioned slightly below the upper surface 2 b of the casing 2 (FIG. 5).

When the light guide 14 is disposed in the first space 10 as described above, the tip end portion of the second light guiding lens 21 of the combination member 15 is covered by the cover portion 41.

Hereinafter, the state of light emission from the lamp member 13 and the light guide 14 will be explained (FIGS. 7 and 8).

When light is emitted from the light emission surface 28 a of the light emission element 28 mounted on the circuit board 16, as shown in FIG. 7, after the light emitted downward enters the first light guiding lens 20 through the first incident surface 20 a, a portion of the entering light is internally reflected by an inner surface of the first light guiding lens 20 and then guided by the first light guiding lens 20 toward the first emission surface 20 b.

The light guided by the first light guiding lens 20 is emitted downward from the first emission surface 20 b. The light emitted from the first emission surface 20 b is refracted by the first emission surface 20 b. At this time, since the first emission surface 20 b is slanted downward as the distance in the right-left direction from the vehicle increases, and slanted with respect to the light axis P, the light emitted from the first emission surface 20 b is refracted in a direction away from the door panel 101 of the vehicle, and then a road below at a side of the door panel 101 is illuminated with the emitted light.

In the cross-section of the first light guiding lens 20 taken along the right-left direction, the slant angle of the outer edge 20 d, which corresponds to the outer surface 20 c of the first light guiding lens 20, with respect to the up-down direction is larger than the slant angle of the inner edge 20 e, which corresponds to the outer surface 20 c of the first light guiding lens 20, with respect to the up-down direction. As a result, light is radiated in a direction away from the door panel 101 easily, which makes it possible to prevent unnecessary radiation of light on the door panel 101.

The first emission surface 20 b is slanted upward with respect to the plane perpendicular to the light axis P, in the direction from the outside toward the inside in the right-left direction. As a result, light is radiated to outside of the vehicle easily, which makes it possible to further prevent unnecessary radiation of light on the door panel 101.

As described above, light emitted from the first emission surface 20 b is controlled by the light control surface 8 a such that an illuminated area below the door handle can be restricted within the predetermined range. As a result, light emitted downward from the first emission surface 20 b is less likely to reach the door panel 101, which makes it possible to illuminate a desirable area while preventing radiation of light in an unnecessary direction.

As described above, the lower end portion of the first light guiding lens 20 is positioned inside the upper end portion of the restriction wall portion 8 of the casing 2, and thus the first emission surface 20 b of the first light guiding lens 20 is positioned above the lower surface 2 a of the casing 2. As a result, light radiated outside becomes less visible directly to people around the door handle, which makes it possible to reduce inconvenience caused by the direct view, such as a dazzling feeling or incorrect recognition of objects.

On the other hand, when light is emitted from the light emission surface 28 a of the light emission element 28 mounted on the circuit board 16, a portion of the light emitted obliquely enters the second light guiding lens 21 through the second incident surface 21 a, and the entering light travels toward the first reflection surface 21 c (FIG. 8). The light A and B traveling toward the first reflection surface 21 c is internally reflected by the first reflection surface 21 c, and then travels toward the second reflection surface 21 d or the function surface 21 b.

The light A traveling toward the second reflection surface 21 d is internally reflected by the second reflection surface 21 d, and subsequently enters the third reflection surface 21 e. The light A in the third reflection surface 21 e, except a portion thereof, travels toward the function surface 21 b, and after emitted from the function surface 21 b, enters the light guide 14 through the first light entrance surface 40 a. The portion of the light A, which has been internally reflected by the second reflection surface 21 d and entered the third reflection surface 21 e, is emitted from the third reflection surface 21 e as leaked light, and then enters the light guide 14 through the second light entrance surface 40 b.

On the other hand, the light B, which has been internally reflected by the first reflection surface 21 c and travelled toward the function surface 21 b, enters the third reflection surface 21 e after internally reflected by the function surface 21 b. The light B in the third reflection surface 21 e is emitted from the third reflection surface 21 e and then enters the light guide 14 through the second light entrance surface 40 b.

The light having entered into the light guide 14 through the first light entrance surface 40 a is guided through the extending portion 38 and emitted from the light output surface 14 a. The light having entered the light guide 14 from the second light entrance surface 40 b is guided through the wide width portion 37 or the slant portion 39 and emitted from the light output surface 14 a.

A portion of the light, which is guided through the light guide 14 and reaches the internal reflection surface 39 a or the internal reflection surface 38 a, is internally reflected by the internal reflection surface 39 a or the internal reflection surface 38 a, and then guided to the light output surface 14 a. The upper end portion of the light guide 14 is subjected to surface texturing. The light is also internally reflected by the portion subjected to the surface texturing and guided to the light output surface 14 a.

As described above, the light having entered the light guide 14 is guided through the wide width portion 37, the slant portion 39, or the extending portion 38 and then emitted from the light output surface 14 a. As a result, the whole light output surface 14 a appears luminous. 

1.-2. (canceled)
 3. A door handle comprising: a casing inside which an accommodation space is provided; and a lamp unit disposed in the accommodation space, wherein: the lamp unit includes a light emission element, a circuit board on which the light emission element is mounted, a housing that supports the circuit board, and a light guiding lens that guides light emitted from the light emission element in a predetermined direction; and the light guiding lens includes an incident surface that receives light emitted from the light emission element, and an emission surface that emits the light entering in the light guiding lens through the incident surface and is positioned below the incident surface; and the emission surface is positioned above a lower surface of the casing, wherein the light guiding lens has a columnar shape extending in an up-down direction; the casing includes a light control surface provided at a lower side of the light guiding lens to be continuous with an outer surface of the light guiding lens; the light control surface has a shape flared downward within a predetermined range; the door handle is provided in a vehicle; and in a cross-section of the light guiding lens taken along a right-left direction of the vehicle, a slant angle of an outer edge of the light guiding lens in the right-left direction with respect to an up-down direction of the vehicle is larger than a slant angle of an inner edge of the light guiding lens in the right-left direction with respect to the up-down direction.
 4. The door handle according to claim 3, wherein: the emission surface is slanted upward with respect to a plane perpendicular to a light axis of light emitted from the light emission element, in a direction from an outside of the vehicle toward an inside of the vehicle in a right-left direction of the vehicle. 